Muscle metabolic responses to exercise above and below the "critical power" assessed using 31P-MRS.

We tested the hypothesis that the asymptote of the hyperbolic relationship between work rate and time to exhaustion during muscular exercise, the "critical power" (CP), represents the highest constant work rate that can be sustained without a progressive loss of homeostasis [as assessed using (31)P magnetic resonance spectroscopy (MRS) measurements of muscle metabolites]. Six healthy male subjects initially completed single-leg knee-extension exercise at three to four different constant work rates to the limit of tolerance (range 3-18 min) for estimation of the CP (mean +/- SD, 20 +/- 2 W). Subsequently, the subjects exercised at work rates 10% below CP (<CP) for 20 min and 10% above CP (>CP) for as long as possible, while the metabolic responses in the contracting quadriceps muscle, i.e., phosphorylcreatine concentration ([PCr]), P(i) concentration ([P(i)]), and pH, were estimated using (31)P-MRS. All subjects completed 20 min of <CP exercise without duress, whereas the limit of tolerance during >CP exercise was 14.7 +/- 7.1 min. During <CP exercise, stable values for [PCr], [P(i)], and pH were attained within 3 min after the onset of exercise, and there were no further significant changes in these variables (end-exercise values = 68 +/- 11% of baseline [PCr], 314 +/- 216% of baseline [P(i)], and pH 7.01 +/- 0.03). During >CP exercise, however, [PCr] continued to fall to the point of exhaustion and [P(i)] and pH changed precipitously to values that are typically observed at the termination of high-intensity exhaustive exercise (end-exercise values = 26 +/- 16% of baseline [PCr], 564 +/- 167% of baseline [P(i)], and pH 6.87 +/- 0.10, all P < 0.05 vs. <CP exercise). These data support the hypothesis that the CP represents the highest constant work rate that can be sustained without a progressive depletion of muscle high-energy phosphates and a rapid accumulation of metabolites (i.e., H(+) concentration and [P(i)]), which have been associated with the fatigue process.

[1]  G. Lamb,et al.  Intracellular Acidosis Enhances the Excitability of Working Muscle , 2004, Science.

[2]  Vanhamme,et al.  Improved method for accurate and efficient quantification of MRS data with use of prior knowledge , 1997, Journal of magnetic resonance.

[3]  Y Fukuba,et al.  A metabolic limit on the ability to make up for lost time in endurance events. , 1999, Journal of applied physiology.

[4]  S. Ward,et al.  Dynamics of intramuscular 31P-MRS P(i) peak splitting and the slow components of PCr and O2 uptake during exercise. , 2002, Journal of applied physiology.

[5]  R. Hugh Morton,et al.  The critical power and related whole-body bioenergetic models , 2006, European Journal of Applied Physiology.

[6]  D. Hill,et al.  Modeling the relationship between velocity and time to fatigue in rowing. , 2003, Medicine and science in sports and exercise.

[7]  H. Monod,et al.  THE WORK CAPACITY OF A SYNERGIC MUSCULAR GROUP , 1965 .

[8]  W. Mechelen,et al.  Metabolic Changes in Single Human Muscle Fibres During Brief Maximal Exercise , 2001 .

[9]  F. Fuchs,et al.  The interaction of cations with the calcium-binding site of troponin. , 1970, Biochimica et biophysica acta.

[10]  Håkan Westerblad,et al.  Muscle fatigue: lactic acid or inorganic phosphate the major cause? , 2002, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[11]  Akira Kan,et al.  The curvature constant parameter of the power-duration curve for varied-power exercise. , 2003, Medicine and science in sports and exercise.

[12]  D. Bishop,et al.  The Critical Power Function is Dependent on the Duration of the Predictive Exercise Tests Chosen , 1998, International journal of sports medicine.

[13]  A. de Haan,et al.  Myosin heavy chain isoform expression and high energy phosphate content in human muscle fibres at rest and post‐exercise. , 1996, The Journal of physiology.

[14]  R. Hughson,et al.  A High Velocity Treadmill Running Test to Assess Endurance Running Potential* , 1984, International journal of sports medicine.

[15]  G. Luciani,et al.  The inhibition of rabbit skeletal muscle contraction by hydrogen ions and phosphate. , 1988, The Journal of physiology.

[16]  D. Gadian,et al.  Bioenergetics of intact human muscle. A 31P nuclear magnetic resonance study. , 1983, Molecular biology & medicine.

[17]  A Garfinkel,et al.  Estimation of critical power with nonlinear and linear models. , 1995, Medicine and science in sports and exercise.

[18]  S A Ward,et al.  Metabolic and respiratory profile of the upper limit for prolonged exercise in man. , 1988, Ergonomics.

[19]  Andrew M. Jones,et al.  Influence of endurance training on muscle [PCr] kinetics during high-intensity exercise. , 2007, American journal of physiology. Regulatory, integrative and comparative physiology.

[20]  S. Ward,et al.  Influence of exercise intensity on the on‐ and off‐transient kinetics of pulmonary oxygen uptake in humans , 2001, The Journal of physiology.

[21]  J. Bangsbo,et al.  Effect of muscle acidity on muscle metabolism and fatigue during intense exercise in man. , 1996, The Journal of physiology.

[22]  B Bigland-Ritchie,et al.  Fatigue of submaximal static contractions. , 1986, Acta physiologica Scandinavica. Supplementum.

[23]  S. Ward,et al.  The effects of training on the metabolic and respiratory profile of high-intensity cycle ergometer exercise , 2006, European Journal of Applied Physiology and Occupational Physiology.

[24]  R. Full,et al.  Aerobic response to exercise of the fastest land crab. , 1983, The American journal of physiology.

[25]  J. Henriksson,et al.  Muscle ATP turnover rate during isometric contraction in humans. , 1986, Journal of applied physiology.

[26]  D. Allen,et al.  Role of phosphate and calcium stores in muscle fatigue , 2001, The Journal of physiology.

[27]  David C. Poole,et al.  Oxygen Uptake Kinetics in Sport, Exercise and Medicine , 2005 .

[28]  K. Sahlin,et al.  Phosphocreatine content in single fibers of human muscle after sustained submaximal exercise. , 1997, The American journal of physiology.

[29]  S. Ward,et al.  Effects of prior exercise on oxygen uptake and phosphocreatine kinetics during high‐intensity knee‐extension exercise in humans , 2001, The Journal of physiology.

[30]  D. Bishop,et al.  The influence of recovery duration between periods of exercise on the critical power function , 1995, European Journal of Applied Physiology and Occupational Physiology.

[31]  Veronique L Billat,et al.  Inter- and intrastrain variation in mouse critical running speed. , 2005, Journal of applied physiology.

[32]  Andrew M. Jones,et al.  Maximal lactate steady state, critical power and EMG during cycling , 2002, European Journal of Applied Physiology.

[33]  A M Jones,et al.  Bioenergetic constraints on tactical decision making in middle distance running , 2002, British journal of sports medicine.

[34]  C. Earnest,et al.  Effect of oral creatine ingestion on parameters of the work rate-time relationship and time to exhaustion in high-intensity cycling , 1998, European Journal of Applied Physiology and Occupational Physiology.

[35]  W. Danforth,et al.  Effect of pH on the kinetics of frog muscle phosphofructokinase. , 1966, The Journal of biological chemistry.

[36]  B. Quigley,et al.  The influence of high-intensity exercise training on the Wlim-Tlim relationship. , 1993, Medicine and science in sports and exercise.

[37]  T. Nosek,et al.  It is diprotonated inorganic phosphate that depresses force in skinned skeletal muscle fibers. , 1987, Science.

[38]  Y. Fukuba,et al.  The effect of oral creatine supplementation on the curvature constant parameter of the power-duration curve for cycle ergometry in humans. , 1999, The Japanese journal of physiology.

[39]  K Wasserman,et al.  A constant which determines the duration of tolerance to high intensity work , 1982 .

[40]  Andrew M. Jones,et al.  The relationship between critical velocity, maximal lactate steady-state velocity and lactate turnpoint velocity in runners , 2001, European Journal of Applied Physiology.

[41]  T. Barstow,et al.  Changes in potential controllers of human skeletal muscle respiration during incremental calf exercise. , 1994, Journal of applied physiology.

[42]  Gregory J. Crowther,et al.  Limits to sustainable muscle performance: interaction between glycolysis and oxidative phosphorylation. , 2001, The Journal of experimental biology.

[43]  Toshio Moritani,et al.  Determination and validity of critical velocity as an index of swimming performance in the competitive swimmer , 2004, European Journal of Applied Physiology and Occupational Physiology.

[44]  David W. Hill,et al.  The Critical Power Concept , 1993, Sports medicine.

[45]  R. Robergs,et al.  Biochemistry of exercise-induced metabolic acidosis. , 2004, American journal of physiology. Regulatory, integrative and comparative physiology.

[46]  R. Fitts Cellular mechanisms of muscle fatigue. , 1994, Physiological reviews.

[47]  T. Barstow,et al.  Effect of work rate on the functional ‘gain’ of Phase II pulmonary O2 uptake response to exercise , 2004, Respiratory Physiology & Neurobiology.

[48]  T. Moritani,et al.  Critical power as a measure of physical work capacity and anaerobic threshold. , 1981, Ergonomics.

[49]  A. V. Hill,et al.  Muscular movement in man : the factors governing speed and recovery from fatigue , 2022 .

[50]  D. Allen,et al.  Cellular mechanisms of skeletal muscle fatigue. , 2003, Advances in experimental medicine and biology.

[51]  N. Vøllestad,et al.  Muscle glycogen depletion patterns in type I and subgroups of type II fibres during prolonged severe exercise in man. , 1984, Acta physiologica Scandinavica.

[52]  Keith Tolfrey,et al.  Oxygen uptake kinetics during moderate, heavy and severe intensity ‘submaximal’ exercise in humans: the influence of muscle fibre type and capillarisation , 2004, European Journal of Applied Physiology.

[53]  Roger G. Eston,et al.  Kinanthropometry and Exercise Physiology Laboratory Manual: Tests, Procedures and Data , 1995 .

[54]  B. Chance,et al.  Relationship of muscular fatigue to pH and diprotonated Pi in humans: a 31P-NMR study. , 1988, Journal of applied physiology.

[55]  D. Bishop,et al.  Ramp and constant power trials produce equivalent critical power estimates. , 1997, Medicine and science in sports and exercise.

[56]  R. Richardson,et al.  The role of oxygen in determining phosphocreatine onset kinetics in exercising humans , 2004, The Journal of physiology.

[57]  Eric G Shankland,et al.  Acidosis inhibits oxidative phosphorylation in contracting human skeletal muscle in vivo , 2003, The Journal of physiology.

[58]  P. D. di Prampero,et al.  Effect of a Previous Sprint on the Parameters of the Work-Time to Exhaustion Relationship in High Intensity Cycling , 2004, International journal of sports medicine.

[59]  D. Hill The relationship between power and time to fatigue in cycle ergometer exercise. , 2004, International journal of sports medicine.

[60]  B. Quigley,et al.  Endurance training enhances critical power. , 1992, Medicine and science in sports and exercise.

[61]  Y. Fukuba,et al.  The effect of glycogen depletion on the curvature constant parameter of the power-duration curve for cycle ergometry , 2000, Ergonomics.

[62]  R. Full Locomotion without lungs: energetics and performance of a lungless salamander. , 1986, The American journal of physiology.

[63]  S. Yamasaki,et al.  Interpretation of 29Si nuclear magnetic resonance spectra of amorphous hydrogenated silicon , 1986 .

[64]  T. Barstow,et al.  Muscle energetics and pulmonary oxygen uptake kinetics during moderate exercise. , 1994, Journal of applied physiology.

[65]  K. Hinchcliff,et al.  Hyperbolic relationship between time-to-fatigue and workload. , 2010, Equine veterinary journal. Supplement.

[66]  C. Fraser,et al.  A 31p Nuclear Magnetic Resonance Study , 1988 .